Terminal device capability transmission method, apparatus, and system

ABSTRACT

Embodiments of this application disclose a terminal device capability transmission method, apparatus, and system. A terminal device reports, to a network device, capability information used to indicate a channel state information CSI reporting capability of the terminal device. The capability information is associated with a quantity, supported by the terminal device in a time-domain unit, of ports of pilots used for CSI measurement, and is used to enable the network device receiving the capability information to learn the CSI reporting capability of the terminal device, thereby determining a CSI measurement configuration of the terminal device.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.16/371,858, filed on Apr. 1, 2019, which is a continuation ofInternational Application No. PCT/CN2018/093415, filed on Jun. 28, 2018,The International Application claims priority to Chinese PatentApplication No. 201810032046.X, filed on Jan. 12, 2018, All of theafore-mentioned patent applications are hereby incorporated by referencein their entireties.

TECHNICAL FIELD

This application relates to the field of communications technologies,and more specifically, to a terminal device capability transmissiontechnology in a communications system.

BACKGROUND

Next-generation mobile communications systems require large-capacityhigh-quality data transmission. A massive multi-input multi-output(Massive MIMO) technology is considered as one of key technologies thatcan implement future high-speed data transmission. The technologysignificantly improves spectral efficiency by using massive antennas.Accuracy of channel state information (CSI) that can be obtained by abase station determines massive MIMO performance to a large extent. Thechannel state information (CSI) is obtained and reported by userequipment (UE) by measuring a downlink transmission channel andquantizing a measurement result, so that the base station can obtain achannel status and an interference status in downlink transmission.

For CSI measurement and result reporting, the base station needs topre-configure corresponding CSI measurement and reporting parametersbased on a CSI reporting capability of the UE. In several releases suchas R11, R12, and R13 in a Long Term Evolution (LTE) communicationssystem, the CSI reporting capability of the UE is defined as a quantity,reported by the UE, of CSI processes that can be processed by the UE.New Radio (NR) defines a set of flexible CSI configuration frameworks.When CSI measurement is to be performed, the base station configures onemeasurement setting, one or more reporting settings, and one or moreresource settings. Each measurement setting includes one or more links.Each link is used to connect one reporting setting and one resourcesetting, and indicate whether the link is used for channel measurementor interference measurement. Each reporting setting includes content ofCSI reporting and occupied time-domain and frequency-domain resourcelocations. Each resource setting includes time-domain andfrequency-domain resource locations occupied by a reference signal (RS)resource used for CSI measurement. Currently, a potential mannerdescribed in NR is to define the CSI reporting capability of the UE as aquantity, reported by the UE, of reporting settings that can beprocessed by the UE.

However, because the CSI process and the reporting setting each havemany configurations, the UE can estimate a reporting capability basedonly on a worst case (that is, a most calculation-consuming case).Therefore, regardless of the quantity of CSI processes or the quantityof reporting settings, an actual calculation capability of the UE interms of CSI reporting cannot be represented, and a degree of freedom inCSI measurement and reporting is restricted.

SUMMARY

This application provides a terminal device capability transmissionmethod, apparatus, and system, so that a network side can learn anactual CSI reporting capability of a terminal device throughtransferring of capability information that represents a more actualcalculation capability of the terminal device in terms of CSI reporting,thereby effectively and flexibly performing CSI measurement relatedconfiguration.

According to a first aspect, a terminal device capability reportingmethod and apparatus are provided.

In a possible design, the method is applied to a terminal device. Anetwork side can obtain an actual CSI reporting capability of theterminal device through reporting of capability information thatrepresents a more actual calculation capability of the terminal devicein terms of CSI reporting. The method includes: The terminal devicesends the capability information of the terminal device to a networkdevice (it may be understood that the network device includes an accessnode, a transmission and reception point having some functions of theaccess node, and the like). The capability information is used toindicate a channel state information CSI reporting capability of theterminal device. It may be understood that before sending the capabilityinformation, the terminal device first generates the capabilityinformation. The capability information is used to enable the networkdevice receiving the information to learn the CSI reporting capabilityof the terminal device, thereby determining a CSI measurementconfiguration of the terminal device. The capability information isassociated with a quantity, supported by the terminal device in at leastone time-domain unit, of ports of pilots used for CSI measurement. Afterestablishing a connection to the network device, the terminal devicereports the capability information. After the network device determinesa capability that is of the terminal device and is associated with thequantity, supported by the terminal device in the at least onetime-domain unit, of ports of the pilots used for CSI measurement, theCSI measurement configuration may be considered based on the capabilityin combination with a status of the network device and/or the terminaldevice. For example, a configuration of the pilot used for CSImeasurement cannot exceed a processing capability of the terminaldevice, the terminal device can complete processing of corresponding CSImeasurement when needing to perform reporting, and can performreporting, and a time for configuring or triggering the terminal deviceto perform reporting is appropriate.

In this design, the terminal device reports the capability information,where the capability information can reflect the actual CSI reportingcapability of the terminal device and is associated with the quantity,supported by the terminal device in the at least one time-domain unit,of ports of the pilots used for CSI measurement, so that the networkdevice can learn the actual CSI reporting capability of the terminaldevice, thereby effectively and flexibly configuring CSI measurement andreporting of the terminal device.

Correspondingly, the terminal device capability reporting apparatus isprovided. The apparatus can implement the corresponding reporting methodaccording to the first aspect. For example, the apparatus is limited ina functional form, and may be an entity on a terminal side. A specificimplementation of the apparatus may be a terminal device. For example,the apparatus may be a terminal device, or a chip or a function modulein a terminal device. The method may be implemented by software orhardware, or by hardware executing corresponding software.

In a possible design, the apparatus may include a processor and amemory. The processor is configured to support the apparatus inexecuting a corresponding function in the method according to the firstaspect. The memory is configured to couple to the processor. The memorystores a program (instruction) and data necessary for the apparatus. Inaddition, the apparatus may further include a communications interface,configured to support communication between the apparatus and anothernetwork element. The communications interface may be a transceiver.

In a possible design, the apparatus may include a transceiver unit. Thetransceiver unit is configured to send the capability information to thenetwork device. Optionally, the apparatus may further include aprocessing unit. The processing unit is configured to generate thecapability information to be sent.

According to a second aspect, a terminal device capability obtainingmethod and apparatus are provided.

In a possible design, the method is applied to a network device, forexample, an access node, or a transmission and reception point havingsome functions of an access node on a network side. The network deviceobtains capability information that is reported by a terminal device andthat represents a more actual calculation capability of the terminaldevice in terms of CSI reporting, so that the network device obtains anactual CSI reporting capability of the terminal device, therebydetermining a subsequent CSI measurement related configuration. Themethod includes: The network device receives the capability informationsent by the terminal device. The capability information is used toindicate a channel state information CSI reporting capability of theterminal device. It may be understood that the capability information isused to enable the network device receiving the information to learn theCSI reporting capability of the terminal device, thereby determining aCSI measurement configuration of the terminal device. The capabilityinformation is associated with a quantity, supported by the terminaldevice in at least one time-domain unit, of ports of pilots used for CSImeasurement. After establishing a connection to the network device, theterminal device reports the capability information. After the networkdevice determines a capability that is of the terminal device and isassociated with the quantity, supported by the terminal device in the atleast one time-domain unit, of ports of the pilots used for CSImeasurement, the CSI measurement configuration may be considered basedon the capability in combination with a status of the network deviceand/or the terminal device. For example, a configuration of the pilotused for CSI measurement cannot exceed a processing capability of theterminal device, the terminal device can complete processing ofcorresponding CSI measurement when needing to perform reporting, and canperform reporting, and a time for configuring or triggering the terminaldevice to perform reporting is appropriate.

In this design, the network device receives the capability informationreported by the terminal device, where the capability information canreflect the actual CSI reporting capability of the terminal device andis associated with the quantity, supported by the terminal device in theat least one time-domain unit, of ports of the pilots used for CSImeasurement, so that the network device can learn the actual CSIreporting capability of the terminal device, thereby effectively andflexibly configuring CSI measurement and reporting of the terminaldevice.

Correspondingly, the terminal device capability obtaining apparatus isprovided. The apparatus can implement the corresponding obtaining methodaccording to the second aspect. For example, the apparatus is limited ina functional form, and may be an entity on an access side. A specificimplementation of the apparatus may be an access node device. Forexample, the apparatus may be an access node device, or a chip or afunction module in an access node device. The method may be implementedby software or hardware, or by hardware executing correspondingsoftware.

In a possible design, the apparatus may include a processor and amemory. The processor is configured to support the apparatus inexecuting a corresponding function in the method according to the secondaspect. The memory is configured to couple to the processor. The memorystores a program (instruction) and data necessary for the apparatus. Inaddition, the apparatus may further include a communications interface,configured to support communication between the apparatus and anothernetwork element. The communications interface may be a transceiver.

In a possible design, the apparatus may include a transceiver unit. Thetransceiver unit is configured to receive the capability informationsent by the terminal device. Optionally, the apparatus may furtherinclude a processing unit. The processing unit is configured todetermine the CSI measurement configuration of the terminal device.

In either technical solution provided in the first aspect and the secondaspect, optionally, the capability information can be indicated by usinga bit in a bitmap or by using a value of an indication field. Thequantity of ports of the pilots used for CSI measurement may include atleast one of the following: a quantity of ports of pilots used forchannel measurement, a sum of the quantity of ports of the pilots usedfor channel measurement and a quantity of ports of pilots used forinterference measurement, and a weighted sum of the quantity of ports ofthe pilots used for channel measurement and the quantity of ports of thepilots used for interference measurement.

Based on either technical solution provided in the first aspect and thesecond aspect, in a possible design, the capability information includesat least one of the following: information about the quantity, supportedin the at least one time-domain unit, of the ports of the pilots usedfor CSI measurement; and information about a quantity of time-domainunits required for supporting a predetermined quantity of ports of thepilots used for CSI measurement (namely, information about a quantity oftime-domain units required for calculating a calculation amountcorresponding to the predetermined quantity of ports). Optionally, thepredetermined quantity of ports may be determined according to differentsettings or policies. For example, the predetermined quantity of portsincludes at least one of the following: a preset minimum configurablequantity of ports that is supported by the terminal device, a presetmaximum configurable quantity of ports that is supported by the terminaldevice, and a quantity of ports that is determined according to apredetermined configuration criterion.

A quantity, supported in one time-domain unit, of ports of pilots usedfor CSI measurement can be determined by using the predeterminedquantity of ports of the pilots used for CSI measurement and thequantity of required time-domain units. Alternatively, the quantity ofrequired time-domain units can be determined by using the predeterminedquantity of ports of the pilots used for CSI measurement and a quantity,supported in one time-domain unit, of ports of pilots used for CSImeasurement. Optionally, the information about the quantity, supportedin the at least one time-domain unit, of ports of the pilots used forCSI measurement includes information about a maximum quantity, supportedin the at least one time-domain unit, of ports of the pilots used forCSI measurement, and the information about the quantity of time-domainunits required for supporting the predetermined quantity of ports of thepilots used for CSI measurement includes information about a minimumquantity of time-domain units required for supporting the predeterminedquantity of ports of the pilots used for CSI measurement. The supportedmaximum quantity of ports and the minimum quantity of requiredtime-domain units reflect a maximum limit to the CSI reportingcapability of the terminal device.

Based on either technical solution provided in the first aspect and thesecond aspect, in a possible design, the time-domain unit may include atleast one of the following division types: n time-domain symbols, nmini-slots, n slots, n subframes, and n frames, where n is greater thanor equal to 1. For example, when the division type is n symbols and n=1,the capability information is associated with a quantity, supported bythe terminal device in one symbol, of ports of the pilots used for CSImeasurement. For example, a quantity, supported in one symbol, of portsof the pilots used for CSI measurement, a quantity of symbols requiredfor supporting a predetermined quantity of ports of the pilots used forCSI measurement. In this design, the CSI reporting capability of theterminal device may be determined based on different calculation amountsand time granularities.

It may be understood that if the terminal device supports a plurality ofdivision types of the time-domain unit, the terminal device may select adivision type used by the terminal device to measure the CSI reportingcapability of the terminal device, and then send, to the network device,first indication information indicating the division type of thetime-domain unit. The first indication information and the capabilityinformation may be sent separately or together. Optionally, a divisiontype may be specified by the network device. The terminal devicereceives, before generating the capability information to be sent,second indication information that indicates a division type and that issent by the network device. The CSI reporting capability of the terminaldevice may be flexibly defined based on an indication of the divisiontypes.

Based on either technical solution provided in the first aspect and thesecond aspect, in a possible design, when the CSI reporting capabilityis further associated with a calculation capability category of theterminal device, the capability information includes the informationabout the quantity of time-domain units required for supporting thepredetermined quantity of ports of the pilots used for CSI measurement.Optionally, if the calculation capability category includes that theterminal device does not have a plurality of parallel calculationchannels for a CSI measurement reporting setting and the at least onetime-domain unit supports calculation of one reporting setting, thecapability information includes the information about the quantity oftime-domain units required for supporting the predetermined quantity ofports of the pilots used for CSI measurement. Optionally, if thecalculation capability category includes that the terminal device has aplurality of parallel calculation channels for a CSI measurementreporting setting and one parallel calculation channel corresponds tocalculation of one reporting setting, the capability informationincludes the information about the quantity of time-domain unitsrequired for supporting the predetermined quantity of ports of thepilots used for CSI measurement and a quantity of the parallelcalculation channels. Optionally, if the calculation capability categoryincludes that the terminal device has a plurality of parallelcalculation channels for a CSI measurement reporting setting and theplurality of parallel calculation channels correspond to parallelcalculation of one reporting setting, the capability informationincludes the information about the quantity of time-domain unitsrequired for supporting the predetermined quantity of ports of thepilots used for CSI measurement.

It may be understood that if the terminal device supports at least twocalculation capability categories, the terminal device may select acalculation capability category used by the terminal device to measurethe CSI reporting capability of the terminal device, and then send, tothe network device, third indication information indicating thecalculation capability category. The third indication information andthe capability information may be sent separately or together.Optionally, a calculation capability category may be specified by thenetwork device. The terminal device receives, before generating thecapability information to be sent, fourth indication information thatindicates the calculation capability category and that is sent by thenetwork device. The CSI reporting capability of the terminal device maybe flexibly defined based on a calculation capability category selectionindication.

Based on either technical solution provided in the first aspect and thesecond aspect, in a possible design, the CSI reporting capability may bedistinguished for different CSI measurement types, or may not bedistinguished. Optionally, if the CSI reporting capability is fordifferent CSI measurement types, the capability information includes atleast one capability information, which indicates at least one CSIreporting capability corresponding to different CSI measurement types.Optionally, if the CSI reporting capability is not for different CSImeasurement types, the capability information indicates a CSI reportingcapability corresponding to a predetermined type in different CSImeasurement types. To consider a most conservative case (that is, a mostcalculation-consuming case is considered to avoid that the capability ofthe terminal device is exceeded), the predetermined type is a maximumcomplexity type. Optionally, the different CSI measurement types includeat least one of the following: different codebook types, differentprecoding matrix indicator PMI types, and different bandwidth part BWPsizes. In this design, the CSI reporting capability of the terminaldevice can be more finely distinguished.

In either technical solution provided in the first aspect and the secondaspect, after the terminal device reports the capability information tothe network device, the network device sends, to the terminal deviceafter determining a configuration, a CSI measurement related parameterconfigured based on the capability information. The terminal devicereceives the CSI measurement related parameter that is sent by thenetwork device and that is configured based on the capabilityinformation. Optionally, the related parameter includes at least one ofthe following: a quantity of reporting settings, a quantity of resourcesettings, a quantity of CSI pilot resource settings included in eachresource set, a quantity of CSI pilot resources included in eachresource set, a quantity of ports of a CSI pilot included in eachresource set, a periodically reported period, and an aperiodicallyreported time offset, where the time offset is a time interval from CSIreporting triggering to CSI reporting.

According to a third aspect, a terminal device capability reportingmethod and apparatus are provided.

In a possible design, the method is applied to a terminal device. A CSIreporting capability of the terminal device is distinguished fordifferent CSI measurement types, so that a network side obtains a moretargeted CSI reporting capability of the terminal device. The methodincludes: The terminal device sends at least two pieces of capabilityinformation of the terminal device to a network device (it may beunderstood that the network device includes an access node, atransmission and reception point having some functions of an accessnode, and the like). The at least two pieces of capability informationare respectively used to indicate CSI reporting capabilities of theterminal device that correspond to different CSI measurement types. Itmay be understood that before sending the at least two pieces ofcapability information, the terminal device first generates thecapability information. The at least two pieces of capabilityinformation may be sent together or separately. It may be understoodthat the capability information is used to enable the network devicereceiving the information to learn the CSI reporting capability of theterminal device, thereby determining a CSI measurement configuration ofthe terminal device in a case of the different CSI measurement types.Optionally, the different CSI measurement types include at least one ofthe following: different codebook types, different precoding matrixindicator PMI types, and different bandwidth part BWP sizes.

In this design, the CSI reporting capability of the terminal device canbe more finely distinguished based on the different CSI measurementtypes, so that the network device determines a more targeted CSImeasurement related configuration of the terminal device.

In a possible design, the related definition in the first aspect or thesecond aspect may be used for the at least two pieces of capabilityinformation. To be specific, the capability information is associatedwith a quantity, supported by the terminal device in at least onetime-domain unit, of ports of pilots used for CSI measurement.

Correspondingly, the terminal device capability reporting apparatus isprovided. The apparatus can implement the corresponding reporting methodaccording to the third aspect. For example, the apparatus is limited ina functional form, and may be an entity on a terminal side. A specificimplementation of the apparatus may be a terminal device. For example,the apparatus may be a terminal device, or a chip or a function modulein a terminal device. The method may be implemented by software orhardware, or by hardware executing corresponding software.

In a possible design, the apparatus may include a processor and amemory. The processor is configured to support the apparatus inexecuting a corresponding function in the method according to the thirdaspect. The memory is configured to couple to the processor. The memorystores a program (instruction) and data necessary for the apparatus. Inaddition, the apparatus may further include a communications interface,configured to support communication between the apparatus and anothernetwork element. The communications interface may be a transceiver.

In a possible design, the apparatus may include a transceiver unit. Thetransceiver unit is configured to send the at least two pieces ofcapability information to the network device. Optionally, the apparatusmay further include a processing unit. The processing unit is configuredto generate the at least two pieces of capability information to besent.

According to a fourth aspect, a terminal device capability obtainingmethod and apparatus are provided.

In a possible design, the method is applied to a network device, forexample, an access node, or a transmission and reception point havingsome functions of an access node on a network side. A CSI reportingcapability of a terminal device is distinguished for different CSImeasurement types, so that the network device obtains a more targetedCSI reporting capability of the terminal device, thereby configuring CSImeasurement of the terminal device in a more targeted manner. The methodincludes: The network device receives at least two pieces of capabilityinformation sent by the terminal device. The at least two pieces ofcapability information are respectively used to indicate CSI reportingcapabilities of the terminal device that correspond to different CSImeasurement types. It may be understood that the capability informationis used to enable the network device to learn the CSI reportingcapability of the terminal device, thereby determining a CSI measurementconfiguration of the terminal device in a case of the different CSImeasurement types. It may be understood that the at least two pieces ofcapability information may be sent together or separately. Optionally,the different CSI measurement types include at least one of thefollowing: different codebook types, different precoding matrixindicator PMI types, and different bandwidth part BWP sizes.

In this design, the CSI reporting capability of the terminal device canbe more finely distinguished based on the different CSI measurementtypes, so that the network device determines a more targeted CSImeasurement related configuration of the terminal device.

In a possible design, the related definition in the first aspect or thesecond aspect may be used for the at least two pieces of capabilityinformation. That is, the capability information is associated with aquantity, supported by the terminal device in at least one time-domainunit, of ports of pilots used for CSI measurement.

Correspondingly, the terminal device capability obtaining apparatus isprovided. The apparatus can implement the corresponding obtaining methodaccording to the fourth aspect. For example, the apparatus is limited ina functional form, and may be an entity on an access side. A specificimplementation of the apparatus may be an access node device. Forexample, the apparatus may be an access node device, or a chip or afunction module in an access node device. The method may be implementedby software or hardware, or by hardware executing correspondingsoftware.

In a possible design, the apparatus may include a processor and amemory. The processor is configured to support the apparatus inexecuting a corresponding function in the method according to the fourthaspect. The memory is configured to couple to the processor. The memorystores a program (instruction) and data necessary for the apparatus. Inaddition, the apparatus may further include a communications interface,configured to support communication between the apparatus and anothernetwork element. The communications interface may be a transceiver.

In a possible design, the apparatus may include a transceiver unit. Thetransceiver unit is configured to receive the at least two pieces ofcapability information sent by the terminal device. Optionally, theapparatus may further include a processing unit. The processing unit isconfigured to determine the CSI measurement configuration of theterminal device.

According to a fifth aspect, a terminal device capability reportingmethod and apparatus are provided.

In a possible design, the method is applied to a terminal device. A CSIreporting capability of the terminal device may be flexibly defined byproviding different definition type selections for the CSI reportingcapability of the terminal device. A network device may performconfiguration in different granularities for different terminal devices.The method includes: The terminal device sends selection indicationinformation to the network device (it may be understood that the networkdevice includes an access node, a transmission and reception pointhaving some functions of an access node, and the like), or the terminaldevice receives selection indication information sent by the networkdevice. The selection indication information is used to indicate a CSIreporting capability definition type of the terminal device. It may beunderstood that when the CSI reporting capability of the terminal devicemay have a plurality of definition types, before generating capabilityinformation indicating the CSI reporting capability, the terminal devicefirst autonomously selects a CSI reporting capability definition type ordetermines a CSI reporting capability definition type based on anindication on a network side.

Optionally, the definition type may be the division type of thetime-domain unit in a definition of the CSI reporting capability in thefirst aspect or the second aspect, a type of the calculation capabilitycategory of the terminal device described above, or another definitiontype.

In this design, the CSI reporting capability of the terminal device maybe flexibly defined by providing different definition type selectionsfor the CSI reporting capability of the terminal device. The networkdevice may perform configuration in different granularities fordifferent terminal devices.

In a possible design, the related definition in the first aspect or thesecond aspect may be used for the capability information. That is, thecapability information is associated with a quantity, supported by theterminal device in at least one time-domain unit, of ports of pilotsused for CSI measurement.

Correspondingly, the terminal device capability reporting apparatus isprovided. The apparatus can implement the corresponding reporting methodaccording to the fifth aspect. For example, the apparatus is limited ina functional form, and may be an entity on a terminal side. A specificimplementation of the apparatus may be a terminal device. For example,the apparatus may be a terminal device, or a chip or a function modulein a terminal device. The method may be implemented by software orhardware, or by hardware executing corresponding software.

In a possible design, the apparatus may include a processor and amemory. The processor is configured to support the apparatus inexecuting a corresponding function in the method according to the fifthaspect. The memory is configured to couple to the processor. The memorystores a program (instruction) and data necessary for the apparatus. Inaddition, the apparatus may further include a communications interface,configured to support communication between the apparatus and anothernetwork element. The communications interface may be a transceiver.

In a possible design, the apparatus may include a transceiver unit. Thetransceiver unit is configured to send the selection indicationinformation to the network device or receive the selection indicationinformation sent by the network device. Optionally, the apparatus mayfurther include a processing unit. The processing unit is configured togenerate the selection indication information to be sent.

According to a sixth aspect, a terminal device capability obtainingmethod and apparatus are provided.

In a possible design, the method is applied to a network device, forexample, an access node, or a transmission and reception point havingsome functions of an access node on a network side. A CSI reportingcapability of a terminal device may be flexibly defined by providingdifferent definition type selections for the CSI reporting capability ofthe terminal device. The network device may perform configuration indifferent granularities for different terminal devices. The methodincludes: The network device sends selection indication information tothe terminal device, or the network device receives selection indicationinformation sent by the terminal device. The selection indicationinformation is used to indicate a CSI reporting capability definitiontype of the terminal device. It may be understood that when the CSIreporting capability of the terminal device may have a plurality ofdefinition types, before generating capability information indicatingthe CSI reporting capability, the terminal device first autonomouslyselects a CSI reporting capability definition type or determines a CSIreporting capability definition type based on an indication on a networkside.

Optionally, the definition type may be the division type of thetime-domain unit in a definition of the CSI reporting capability in thefirst aspect or the second aspect, a type of the calculation capabilitycategory of the terminal device described above, or another definitiontype.

In this design, the CSI reporting capability of the terminal device maybe flexibly defined by providing different definition type selectionsfor the CSI reporting capability of the terminal device. The networkdevice may perform configuration in different granularities fordifferent terminal devices.

In a possible design, the related definition in the first aspect or thesecond aspect may be used for the capability information. That is, thecapability information is associated with a quantity, supported by theterminal device in at least one time-domain unit, of ports of pilotsused for CSI measurement.

Correspondingly, the terminal device capability obtaining apparatus isprovided. The apparatus can implement the corresponding obtaining methodaccording to the sixth aspect. For example, the apparatus is limited ina functional form, and may be an entity on an access side. A specificimplementation of the apparatus may be an access node device. Forexample, the apparatus may be an access node device, or a chip or afunction module in an access node device. The method may be implementedby software or hardware, or by hardware executing correspondingsoftware.

In a possible design, the apparatus may include a processor and amemory. The processor is configured to support the apparatus inexecuting a corresponding function in the method according to the sixthaspect. The memory is configured to couple to the processor. The memorystores a program (instruction) and data necessary for the apparatus. Inaddition, the apparatus may further include a communications interface,configured to support communication between the apparatus and anothernetwork element. The communications interface may be a transceiver.

In a possible design, the apparatus may include a transceiver unit. Thetransceiver unit is configured to send the selection indicationinformation to the terminal device or receive the selection indicationinformation sent by the terminal device. Optionally, the apparatus mayfurther include a processing unit. The processing unit is configured todetermine the CSI measurement configuration of the terminal device.

This application further provides a computer storage medium, storing acomputer program (instruction). When the program (instruction) runs on acomputer, the computer performs the method according to any one of theforegoing aspects.

This application further provides a computer program product. When thecomputer program product runs on a computer, the computer performs themethod according to any one of the foregoing aspects.

This application further provides a terminal device capabilitytransmission chip, storing an instruction. When the instruction runs ona communications device, the communications device performs thecorresponding methods according to the foregoing aspects.

This application further provides a terminal device capabilitytransmission apparatus. The apparatus includes a memory, a processor,and a computer program that is stored in the memory and that can run inthe processor. When executing the computer program, the processorimplements the corresponding methods according to the foregoing aspects.

This application further provides a terminal device capabilitytransmission apparatus. The apparatus includes a processor. Theprocessor is configured to: couple to a memory, read an instruction inthe memory, and implement, based on the instruction, the correspondingmethods according to the foregoing aspects. It may be understood thatthe memory may be integrated into the processor, or may existindependent of the processor.

This application further provides a terminal device capabilitytransmission apparatus. The apparatus includes a processor. Whenexecuting a computer program, the processor implements the correspondingmethods according to the foregoing aspects.

This application further provides a terminal device capabilitytransmission system. The system includes the apparatuses on a terminalside provided above, and the apparatuses on a network side providedabove. These system components respectively implement the correspondingmethods according to the foregoing aspects.

It may be understood that any apparatus, computer storage medium,computer program product, chip, or system provided above is configuredto implement the corresponding method provided above. Therefore, forbeneficial effects that can be achieved by the apparatus, computerstorage medium, computer program product, chip, or system, refer tobeneficial effects of the corresponding method. Details are notdescribed herein again.

BRIEF DESCRIPTION OF DRAWINGS

To describe the technical solutions in the embodiments of thisapplication more clearly, the following briefly describes theaccompanying drawings required for describing the embodiments of thisapplication. Apparently, the accompanying drawings in the followingdescription show merely some embodiments of this application, and aperson of ordinary skill in the art may still derive other drawings fromthe embodiments of this application and these accompanying drawingswithout creative efforts.

FIG. 1 shows a network system architecture in this application;

FIG. 2 is a flowchart of a first embodiment of a terminal devicecapability reporting method according to this application;

FIG. 3 is a flowchart of a second embodiment of a terminal devicecapability reporting method according to this application;

FIG. 4 is a flowchart of a third embodiment of a terminal devicecapability reporting method according to this application;

FIG. 5 is a flowchart of a fourth embodiment of a terminal devicecapability reporting method according to this application;

FIG. 6 is a schematic diagram of a configuration manner of configuring,by an access node based on a CSI reporting capability of UE, the UE toperiodically or semi-persistently report CSI according to thisapplication;

FIG. 7 is a schematic diagram of a configuration manner of configuring,by an access node based on a CSI reporting capability of UE, the UE toaperiodically report CSI according to this application;

FIG. 8 is another schematic diagram of a configuration manner ofconfiguring, by an access node based on a CSI reporting capability ofUE, the UE to aperiodically report CSI according to this application;

FIG. 9 is a simplified schematic structural diagram of a terminal deviceaccording to this application; and

FIG. 10 is a simplified schematic structural diagram of a network deviceaccording to this application.

DESCRIPTION OF EMBODIMENTS

To make the technical problems resolved, the technical solutions used,and the technical effects achieved in this application clearer, thefollowing describes the technical solutions in this application withreference to the accompanying drawings in the embodiments. The detaileddescriptions provide various embodiments of a device and/or a process byusing block diagrams, flowcharts, and/or examples. These block diagrams,flowcharts, and/or examples include one or more functions and/oroperations, and therefore a person in the art may understand that eachfunction and/or operation in the block diagrams, the flowcharts, and/orthe examples may be performed independently and/or jointly by using muchhardware, software, and firmware, and/or any combination thereof.

“A plurality of” in this application refers to two or more than two. Theterm “and/or” in this application describes only an associationrelationship for describing associated objects and represents that threerelationships may exist. For example, A and/or B may represent thefollowing three cases: Only A exists, both A and B exist, and only Bexists. In addition, the character “/” in this specification generallyindicates an “or” relationship between the associated objects. In thisapplication, the terms “first”, “second”, “third”, “fourth”, and thelike are intended to distinguish between different objects but do notlimit a sequence of the different objects.

In this application, the nouns “network” and “system” are often usedalternately, but a person skilled in the art may understand the meaningsthereof. In some cases, all “terminals”/“terminal devices” mentioned inthis application may be mobile devices, for example, mobile phones,personal digital assistants, handheld or laptop computers, and similardevices having a telecommunications capability. In some cases, the“terminals”/“terminal devices” may also be wearable devices orin-vehicle devices, and include terminals in a future 5G network,terminals in a future evolved Public Land Mobile Network (PLMN), or thelike. Such a terminal may include a device and a removable storagemodule (for example, but not limited to a universal integrated circuitcard (UICC) including a subscriber identification module (SIM)application, a universal subscriber identification module (USIM)application, or a removable user identity module (R-UIM) application)associated with the device. Alternatively, such a terminal may include adevice that does not have the module. In another case, the terms“terminal”/“terminal device” may be a non-portable device having asimilar capability, for example, a desktop computer, a set top box, or anetwork device. The terms “terminal”/“terminal device” may also be anyhardware or software component that can terminate a communicationsession of a user. In addition, “user terminal”, “User Equipment”, “UE”,“station”, “station”, “STA”, “user equipment”, “user agent”, “UserAgent”, “UA”, “user device”, “mobile device”, “device”, and the like arealternative terminologies synonymous with the “terminal”/“terminaldevice” in this specification. For ease of description, in thisapplication, the devices mentioned above are collectively referred to asuser equipment or UE.

The “access node” mentioned in this application is a network device, isan apparatus deployed in radio access network to provide a wirelesscommunication function for a terminal device, and has functions such asscheduling and configuring a downlink reference signal to UE. The accessnode may include various forms of macro base stations, micro basestations, relay stations, access points, and the like, including systemsand devices for improving peer devices in a conventional wirelesstelecommunications system. Such advanced or next-generation devices maybe included in a Long Term Evolution LTE communications system, a 5Gcommunications system, a future evolved system, or a plurality ofcommunication fusion systems, for example, an evolved universalterrestrial radio access network NodeB (E-UTRAN NodeB, eNB) included inthe LTE system, a new radio access NodeB (NR NodeB) included in 5Ganother radio access point, or a similar component. In systems usingdifferent radio access technologies, a device having an access nodefunction may have different names. For ease of description, in thisapplication, the foregoing apparatuses providing the wirelesscommunication function for the UE are collectively referred to as anaccess node.

FIG. 1 shows a network system architecture in this application. Thesystem is used for UE capability reporting and channel state information(CSI) measurement. The system includes UE 100 and an access node 200.FIG. 1 uses an example of two stages, connection establishment and CSImeasurement, between the UE 100 and the access node 200 in a movementprocess of the UE 100. Optionally, if the network is a network centeredon a user and tracks the user as the user moves, the system furtherincludes at least one transmission and reception point 300 (TRP). Thetransmission and reception point 300 has some functions of an accessnode 200 corresponding to a region in which the transmission andreception point 300 is located, can partially replace the access node200 to interact with the UE 100, and may further have particularfunctions in a particular scenario. For example, the transmission andreception point 300 can listen to an uplink tracking reference signalsent by an inactive user that does not access the network, and performlistening by using the user as a center and moving with the user. Afterthe user establishes a connection to the access node 200, capabilityreporting of the UE may also be sent to the access node 200 by using thetransmission and reception point 300.

After the UE 100 establishes the connection to the access node 200, theUE 100 reports the capability of the UE, so that the access node 200performs corresponding configuration. The reported capability includes aUE capability for CSI reporting, a UE capability for pilotconfiguration, a capability of supporting a CSI measurement type, acache capability, and the like. In this application, the CSI reportingcapability is focused. The UE 100 reports, to the access node 200, CSIreporting capability information related to a quantity, supported in atleast one time-domain unit, of ports of pilots used for CSI measurement.A concept of the pilot may include a reference signal (RS), asynchronization signal block (SSB), a preamble, and the like.Subsequently, this application is described by using the RS to representthe pilot. After receiving a CSI measurement and reporting relatedconfiguration, the access node 200 configures the UE 100 based on thecapability information, including a resource configuration and areporting configuration. Based on the capability information, the accessnode 200 needs to consider whether the CSI measurement configurationexceeds a processing capability of the UE, whether processing ofcorresponding CSI measurement can be completed when the UE 100 needs toperform reporting, and can perform reporting, and an appropriate timefor configuring or triggering the UE 100 to perform reporting.

Then, the CSI measurement stage is performed. The access node 200 sendsa pilot signal to the UE 100 to perform channel measurement andinterference measurement. The UE 100 reports channel state informationCSI, including, for example, a precoding matrix indicator (PMI), a rankindication (RI), and a channel quality indicator (CQI). The UE 100 mayinform, by using the PMI, the access node 200 of an optimal precodingmatrix in current downlink transmission, and inform, by using the RI,the access node 200 of an optimal quantity of layers in the currentdownlink transmission. The CQI indicates, after the suggested RI and PMIare used, an available modulation and coding scheme for ensuring that abit error rate of downlink data receiving does not exceed apredetermined value. The CSI may be periodically or aperiodicallyreported to the access node 200. A difference between the two mannerslies in that reporting configuring or triggering manners are different.

It should be noted that, FIG. 1 shows merely an example of a networksystem architecture in this application, and this application is notlimited thereto. Similarly, this application may also be applied to anIEEE 802.11 system. A station (STA) reports a channel measurementinformation reporting capability of the station to an access point (AP),thereby effectively configuring channel measurement reporting of theSTA.

Embodiment 1

In a network, UE establishes a connection to an access node, and reportsa CSI reporting capability by using a method in this embodiment, so thatthe access node learns of an actual CSI reporting capability of the UE,thereby flexibly configuring CSI measurement and reporting. In thisembodiment and subsequent embodiments, interaction between the UE andthe access node is described merely by way of example. This applicationis not limited thereto. When a transmission and reception point TRPmanaged by the access node in the network has some related functions ofthe access node, this application may further be applied to a scenarioin which the UE interacts with the TRP to report the CSI reportingcapability. According to this embodiment of this application, FIG. 2 isa flowchart of a first embodiment of a terminal device capabilityreporting method according to this application. For ease ofunderstanding the solution, behavior on sides of both the UE and theaccess node is described in this embodiment and the subsequentembodiments. Descriptions are provided from perspectives of allinteracting parties. However, this is in no way limited to thatimprovements in the system are to combine steps of all the interactingparities. The technical solution provided in this application hasimprovements on each side in the system.

The method includes the following steps.

S101. UE generates capability information.

After establishing a connection to the access node, the UE needs toreport, to the access node, capability information of a capabilitysupported by the UE. The reported capability includes a UE capabilityfor CSI reporting, a UE capability for pilot configuration, and thelike. In this application, the CSI reporting capability is focused. TheCSI reporting capability is capability reflection of a calculationcapability of the UE that is related to a CSI reporting requirement.

S102. The UE sends the capability information of the UE to an accessnode.

The capability information is used to indicate a channel stateinformation CSI reporting capability of the UE. The capabilityinformation is associated with a quantity, supported by the UE in atleast one time-domain unit, of ports of pilots (for example, RSs) usedfor CSI measurement. The quantity of ports of the pilots (for example,the RSs) used for CSI measurement may be a quantity of ports for sendingthe pilots (for example, the RSs) used for CSI measurement. The port maybe logically understood as a virtual antenna. The port is defined from aperspective of a receiver. The receiver considers a port as anindependent antenna channel. Ports may be distinguished by usingdifferent time-frequency resource locations, different code-domainextension sequences, and the like. Different ports may be used todistinguish different channels.

There may be one piece of or at least two pieces of capabilityinformation. For different CSI measurement types such as differentcodebook types, different precoding matrix indicator PMI types, ordifferent bandwidth part BWP sizes, optionally, there may be differentcombinations of types, such as different codebook types and differentPMI types, different codebook types and different BWP sizes, differentPMI types and different BWP sizes, or different codebook types,different PMI types, and different BWP sizes. The at least two pieces ofcapability information may respectively indicate CSI reportingcapabilities of the UE for different CSI measurement types. If thecapability information is not distinguished for the different CSImeasurement types, optionally, the CSI reporting capability of the UE isdetermined based on a reporting capability in a case of a particulartype (for example, a maximum complexity type, a maximum time-consumingtype, or a preset specified type). The capability information indicatesa CSI reporting capability in a case of a particular type.

The quantity of ports of the pilots used for CSI measurement includes atleast one of the following: a quantity of ports of pilots used forchannel measurement, a sum of the quantity of ports of the pilots usedfor channel measurement and a quantity of ports of pilots used forinterference measurement, and a weighted sum of the quantity of ports ofthe pilots used for channel measurement and the quantity of ports of thepilots used for interference measurement. Optionally, if calculationcomplexity of the pilot used for interference measurement is less thancomplexity of the pilot used for channel measurement, it may be selectedthat a weighting factor of the quantity of ports of the pilots used forinterference measurement is less than or equal to 1. However, this ismerely an example in this application, and this application is notlimited thereto.

The CSI reporting capability of the UE may be reflected by using thequantity, supported in the at least one time-domain unit, of ports ofthe pilots used for CSI measurement, and optionally, by using a maximumquantity, supported in the at least one time-domain unit, of ports ofthe pilots used for CSI measurement, that is, reflection of a maximumcalculation amount that can be processed by the UE in the at least onetime-domain unit; or by using a quantity, supported in at least onetime-domain unit and determined according to a predetermined policy anddepending on a particular consideration, of ports of pilots used for CSImeasurement, for example, a quantity of ports that reflects an averagecalculation capability or a quantity of ports that can be processed in aparticular scenario. A concept of the pilot may include a referencesignal (RS), a synchronization signal block (SSB), a preamble, and thelike. Subsequently, this application is described by using the RS torepresent the pilot.

The CSI reporting capability of the UE may also be reflected by using aquantity of time-domain units required for supporting a predeterminedquantity of ports of the pilots used for CSI measurement (namely,information about a quantity of time-domain units that is required forcalculating a calculation amount corresponding to the predeterminedquantity of ports). Specifically, for example, the predeterminedquantity of ports is P (P is greater than or equal to 1). Optionally,the predetermined quantity of ports may be a preset minimum configurablequantity of ports that is supported by the UE, a preset maximumconfigurable quantity of ports that is supported by the UE, or aquantity of ports that is determined according to a predeterminedconfiguration criterion. The quantity of time-domain units that isrequired for the P ports is calculated as N (N is greater than or equalto 1). Therefore, P/N is a quantity, supported in each time-domain unit,of ports of the pilots used for CSI measurement. It can be learned thatthe quantity of time-domain units that is required for calculating thepredetermined quantity of ports of the pilots used for CSI measurementis in an indirect association relationship with the quantity, supportedin the at least one time-domain unit, of ports of the pilots used forCSI measurement. Optionally, the quantity of time-domain units that isrequired for calculating the predetermined quantity of ports of thepilots used for CSI measurement may be a minimum quantity of time-domainunits that is required for calculating the predetermined quantity ofports of the pilots used for CSI measurement, that is, reflecting afastest processing speed of the UE, or may be the quantity, determinedaccording to a predetermined policy and depending on a particularconsideration, of time-domain units that is required for calculating thepredetermined quantity of ports of the pilots used for CSI measurement,for example, a quantity of time-domain units reflecting an averagecalculation speed or a quantity of time-domain units corresponding to aprocessing speed in a particular scenario.

It should be noted that, this application is not limited to such two CSIcapability reflection representations, and any direct or indirectrepresentation associated with the quantity, supported in the at leastone time-domain unit, of ports of the pilots used for CSI measurementcan be used in this application. Therefore, a corresponding CSIcapability indicates that the capability information includesinformation about the quantity, supported in the at least onetime-domain unit, of ports of the pilots used for CSI measurement orinformation about the quantity of time-domain units that is required forcalculating the predetermined quantity of ports of the pilots used forCSI measurement.

For division of the time-domain unit, one time-domain unit may includeat least one of the following division types: n time-domain symbols, nmini-slots, n slots, n subframes, n frames, or n time-domain subunitsdefined in another form, where n is greater than or equal to 1.

The capability information may be indicated by using a bit in a bitmapBitmap or by using a value of an indication field. For example, if thecapability information is the foregoing quantity, supported in the atleast one time-domain unit, of ports of the pilots used for CSImeasurement, it is assumed that a quantity of potential values of allpossible CSI reporting capabilities is P. (For example, P is 32. In thiscase, all the possible CSI reporting capabilities have 32 potentialvalues. The 32 potential values correspond to port 1 to port 32,including port 1 and port 32. This is merely an example. The potentialvalues may alternatively correspond to port 1 to port 48, and so on.) Anindication manner by using the bit in the bitmap may be: The bitmap hasa length of P bits, and the following example is described by using anexample in which P is 32. It may be understood that this application isnot limited thereto. Port 1 to port 32 are separately indicated by eachof the 32 bits, and the bit may be set to 1 or 0 for indication. Forexample, the quantity of ports to be reported is M. In this case, theM^(th) bit (a start location is 1) in the bitmap reported by the UE isset to 1 (or 0), and other bits are set to 0 (or 1). When the value ofthe indication field is used for indication, the quantity of ports maybe indicated by using different values of an indication field having alength of ┌log₂ P┐ bits. Likewise, if the capability information is theforegoing quantity of time-domain units that is required for calculatingthe predetermined quantity of ports of the pilots used for CSImeasurement, it is assumed that a quantity of potential values of allpossible CSI reporting capabilities is N. (Likewise, for example, N is16. In this case, all the possible CSI reporting capabilities have 16potential values, for example, unit 1 to unit 16 required forcalculating 32 ports.) An indication manner using the bit in the bitmapmay be: The bitmap has a length of N bits, assuming that the quantity oftime-domain units to be reported is M (that is, calculating the 32 portsrequires M units), the M^(th) bit (a start location is 1) in the bitmapreported by the UE is set to 1 (or 0), and other bits are set to 0 (or1). When the value of the indication field is used for indication, thequantity of time-domain units may be indicated by using different valuesof an indication field having a length of ┌log₂ N┐ bits. It may beunderstood that an indication form is not limited to the foregoingexamples, and all manners that can indicate different types may be usedin this application.

S103. The access node determines a CSI measurement related configurationof the UE based on the received capability information reported by theUE.

The access node determines the CSI measurement related configuration ofthe UE. Optionally, the access node determines a configuration rangebased on the CSI reporting capability of the UE, and then selects adetermined configuration based on a status of the access node and apossible status of the UE. Optionally, the related configuration mayinclude a configuration of the pilot used for CSI measurement, aconfiguration of a corresponding time-frequency resource, and areporting configuration. The following manner is used as an example fordescription, but this application is not limited thereto. For example, abase station configures one measurement setting, one or more reportingsettings, and one or more resource settings based on the receivedcapability information reported by the UE. Each measurement settingincludes one or more links. Each link is used to connect one reportingsetting and one resource set, and indicate whether the measurementsetting is used for channel measurement or interference measurement.Each reporting setting includes content of the CSI reporting andoccupied time-domain and frequency-domain resource locations. Eachresource setting includes time-domain and frequency-domain resourcelocations occupied by a pilot resource used for CSI measurement. Whenthe foregoing content is configured, the access node needs to considerwhether the configuration exceeds a processing capability of the UE,whether processing of corresponding CSI measurement can be completedwhen the UE needs to perform reporting, and can perform reporting, andan appropriate time for configuring or triggering the UE to performreporting. Therefore, optionally, a configuration related parameter mayinclude at least one of the following: a quantity of reporting settings,a quantity of resource settings, a quantity of CSI pilot resourcesettings included in each resource setting, a quantity of CSI pilotresources included in each resource setting, a quantity of ports of aCSI pilot included in each resource setting, a periodically reportedperiod, and an aperiodically reported time offset, where the time offsetis a time interval from CSI reporting triggering to CSI reporting.

For a specific resource configuration policy, refer to detaileddescriptions of FIG. 6 to FIG. 8 below. Details are not describedherein.

S104. The access node sends information about the CSI measurementrelated configuration to the UE.

The UE performs configuration based on the information about the CSImeasurement related configuration that is sent by the access node, andcompletes CSI measurement and reporting based on the configuration.

It should be noted that, the foregoing merely describes a manner ofdefining the CSI reporting capability to be associated with thequantity, supported by the UE in the at least one time-domain unit, ofports of the pilots (for example, the RSs) used for CSI measurement.However, this application is not limited thereto. The CSI reportingcapability may further be defined as a quantity of ports supported in atleast one unit/a quantity of pilots (CSI-RS) used for CSI measurement/aquantity of CSI-RS sets/a quantity of CSI-RS settings. The set mayinclude one or more CSI-RS resources, and the setting may include aplurality of sets.

According to the terminal device capability reporting method in thisembodiment of this application, the capability information that canreflect the actual CSI reporting capability of the UE is reported, sothat the access point can learn the actual CSI reporting capability ofthe UE, thereby flexibly configuring CSI measurement and reporting ofthe UE.

Embodiment 2

FIG. 3 is a flowchart of a second embodiment of a terminal devicecapability reporting method according to this application. A differencebetween this embodiment and Embodiment 1 lies in that, in thisembodiment, definitely, there are at least two CSI reportingcapabilities. Content the same as or similar to that in Embodiment 1 isnot described again in this embodiment. It should be noted that, the CSIreporting capability in this embodiment is not necessarily defined, inthe manner in Embodiment 1, to be associated with the quantity,supported by the UE in the at least one time-domain unit, of ports ofthe pilots used for CSI measurement, and may be a CSI reportingcapability defined for another purpose. The manner in this embodimentmay be used provided that there are at least two CSI reportingcapabilities.

The method includes the following steps.

S201. UE generates capability information.

In a network, when the CSI reporting capabilities of the UE need to bedistinguished for different CSI measurement types, for example, fordifferent codebook types (such as type I and type II), differentprecoding matrix indicator PMI types (such as having a PMI, having noPMI, a narrowband PMI, and a broadband PMI), and different bandwidthpart BWP sizes, optionally, there may be different combinations oftypes, such as different codebook types and different PMI types,different codebook types and different BWP sizes, different PMI typesand different BWP sizes, or different codebook types, different PMItypes, and different BWP sizes.

An access node needs to perform CSI measurement related configurationseparately based on the reporting capabilities of the UE for differentCSI measurement types. Therefore, the CSI reporting capabilities need tobe determined for the different CSI measurement types, to generate atleast two pieces of capability information of the CSI reportingcapabilities corresponding to the different CSI measurement types.

If the CSI reporting capability is defined in the manner in Embodiment1, for details, refer to related descriptions in Embodiment 1. Detailsare not described herein again.

S202. The UE sends the capability information of the UE to an accessnode.

In this embodiment, the capability information includes capabilityinformation of a capability 1, a capability 2, . . . , and a capabilityN each indicating a CSI reporting capability corresponding to thedifferent CSI measurement types.

The CSI reporting capabilities for the different CSI measurement typesmay be correspondingly indicated by using a corresponding formatlocation of each CSI reporting capability (for example, the capability 1or the capability 2) in a signaling format in reporting signaling (forexample, the first piece of capability information corresponds tocodebook type I, and the second piece of capability informationcorresponds to codebook type II). The CSI reporting capabilities mayhave a concatenation relationship in the format (that is, independentfields are connected end-to-end, to indicate more values compared withone field). A meaning corresponding to each value may be differentcodebook types, different PMI types, different BWP sizes, or variouscombinations of the foregoing types.

S203. The access node determines a CSI measurement related configurationof the UE based on the received capability information reported by theUE.

Based on a plurality of pieces of received indication information of theCSI reporting capabilities, the access node performs CSI measurementrelated configuration separately based on the reporting capabilities ofthe UE for the different CSI measurement types. Other content similar toS103 is not described herein again.

S204. The access node sends information about the CSI measurementrelated configuration to the UE.

The UE performs configuration based on the information about the CSImeasurement related configuration that is sent by the access node, andcompletes CSI measurement and reporting based on the configurationduring subsequent CSI measurement.

According to the terminal device capability reporting method in thisembodiment of this application, the UE reports the plurality of CSIreporting capabilities for the different CSI measurement types, so thatthe access point can learn of actual CSI reporting capabilities of theUE for the different CSI measurement types, thereby flexibly configuringCSI measurement and reporting of the UE.

Embodiment 3

FIG. 4 is a flowchart of a third embodiment of a terminal devicecapability reporting method according to this application. A differencebetween this embodiment and Embodiment 1 or 2 lies in that, in thisembodiment, a UE capability reporting procedure is performed when a UEcapability for CSI reporting has different definition type selections.In addition, Embodiment 2 describes a case in which the capabilityinformation has a plurality of capability values, and this embodiment ismainly for a case in which a selected format/definition formcorresponding to each capability value is optional. Content the same asor similar to that in Embodiment 1 or 2 is not described again in thisembodiment. The method includes the following steps.

S301. An access node sends CSI reporting capability definition typeselection indication information to the UE.

When a network includes a plurality of CSI reporting capabilitydefinition types, after establishing a connection to the access node,the UE is uncertain about a definition type of a CSI reportingcapability to be reported to the access node. Therefore, the access nodeneeds to send the CSI reporting capability definition type selectionindication information to the UE, to inform the UE of a definition typeof the CSI reporting capability that is to be determined and reportedsubsequently.

It should be noted that, in this embodiment, a CSI reporting capability,corresponding to the CSI reporting capability definition type selectionindication information is not necessarily defined in the manner inEmbodiment 1, and may be a CSI reporting capability defined for anotherpurpose. The manner in this embodiment may be used for indicationprovided that the CSI reporting capability has a plurality of definitiontypes.

Optionally, in the definition of the CSI reporting capability inEmbodiment 1, the definition type is used for defining different CSIreporting capabilities according to different division types of atime-domain unit. For example, the CSI reporting capability may beassociated with a quantity, supported in n symbols, of ports of pilotsused for CSI measurement, a quantity, supported in n mini-slots, ofports of pilots used for CSI measurement, a quantity, supported in nslots, of ports of pilots used for CSI measurement, a quantity,supported in n subframes, of ports of pilots used for CSI measurement, aquantity, supported in n frames, of ports of pilots used for CSImeasurement, or a quantity, supported in n time-domain subunits definedin another form, of ports of pilots used for CSI measurement, where n isgreater than or equal to 1. Therefore, the definition type selectionindication information may indicate definition type by using adefinition type index or a corresponding bit in a bitmap Bitmap. Forexample, the time-domain unit has four division types, the bitmap mayhave a length of four bits, and each bit corresponds to one type (forexample, n symbols or n slots). A corresponding bit is set to 1 or 0, toindicate a division type (for example, division is performed by nsymbols or n slots) used for dividing the time-domain unit in thedefinition types. The definition type selection indication informationmay be indicated by using a value of an indication field. For example,the time-domain unit has four division types, and the indication fieldmay be two bits. Different values such as 00, 01, 10, and 11 of thefield are used to respectively indicate the corresponding divisiontypes. It may be understood that an indication form is not limited tothe foregoing examples, and all manners that can indicate differenttypes may be used in this application.

Optionally, in a case of the quantity, supported in the at least onetime-domain unit in the definition of the CSI reporting capability inEmbodiment 1, of ports of the pilots used for CSI measurement, for thedefinition type, different CSI reporting capabilities may be defined fordifferent calculation capability categories of the UE. For example, theCSI reporting capability may be associated with whether the UE has aplurality of parallel calculation channels for a CSI measurementreporting setting and whether each time-domain unit supports calculationof one reporting setting, and may include three categories: First, theUE does not have a plurality of parallel calculation channels for theCSI measurement reporting setting and each time-domain unit supportscalculation of one reporting setting. Second, the UE has a plurality ofparallel calculation channels for the CSI measurement reporting settingand one parallel calculation channel corresponds to calculation of onereporting setting. Third, the UE has a plurality of parallel calculationchannels for the CSI measurement reporting setting and the plurality ofparallel calculation channels correspond to parallel calculation of onereporting setting. Therefore, likewise, the definition type selectionindication information may be indicated by using the definition typeindex or the corresponding bit in the bitmap Bitmap, or be indicated byusing the value of the indication field. A specific manner is similar,and details are not described herein again. It may be understood that anindication form is not limited to the foregoing examples, and allmanners that can indicate different types may be used in thisapplication.

S302. The UE generates capability information based on the received CSIreporting capability definition type selection indication information.

According to the foregoing example, if the definition type selectionindication information indicates that the time-domain unit is divided inunits of one slot, the capability information to be reported isgenerated based on an association definition of a quantity, supported ineach slot, of ports of the pilots used for CSI measurement.

According to the foregoing example, if the definition type selectionindication information indicates that the calculation capabilitycategory is the second category described above, the capabilityinformation to be reported is generated based on an associationdefinition in which the UE has a plurality of parallel calculationchannels for the CSI measurement reporting setting and one parallelcalculation channel corresponds to calculation of one reporting setting.

S303. The UE sends the capability information of the UE to the accessnode.

The capability information is used to indicate a channel stateinformation CSI reporting capability of the UE. If the capabilityinformation is associated with a quantity, supported by the UE in atleast one time-domain unit, of ports of pilots, for details, refer torelated descriptions in Embodiment 1. Details are not described hereinagain.

For the three calculation capability categories in the example in S302,in a case of the first category and the third category, optionally, thecapability information includes information about a quantity oftime-domain units required for calculating a predetermined quantity ofports of the pilots used for CSI measurement. In a case of the secondcategory, optionally, the capability information includes informationabout a quantity of time-domain units required for calculating apredetermined quantity of ports of the pilots used for CSI measurementand a quantity of parallel calculation channels.

S304. The access node determines a CSI measurement related configurationof the UE based on the received capability information reported by theUE.

This step is similar to S103, and details are not described hereinagain.

S305. The access node sends information about the CSI measurementrelated configuration to the UE.

The UE performs configuration based on the information about the CSImeasurement related configuration that is sent by the access node, andcompletes CSI measurement and reporting based on the configurationduring subsequent CSI measurement.

According to the terminal device capability reporting method in thisembodiment of this application, the access node sends the CSI reportingcapability definition type selection indication information to the UE,so that the UE can effectively report the CSI reporting capability whenthe system includes the plurality of CSI reporting capability definitiontypes.

Embodiment 4

FIG. 5 is a flowchart of a fourth embodiment of a terminal devicecapability reporting method according to this application. A differencebetween this embodiment and Embodiment 3 lies in that, in thisembodiment, UE reports a definition type selection indication when a UEcapability for CSI reporting has different definition type selections.Content the same as or similar to that in Embodiment 3 is not describedin this embodiment again. It should be noted that, similar to Embodiment3, a CSI reporting capability in this embodiment is not necessarilydefined in the manner in Embodiment 1, and may be a CSI reportingcapability defined for another purpose. The manner in this embodimentmay be used provided that the CSI reporting capability has a pluralityof definition types.

The method includes the following steps.

S401. The UE generates capability information.

When a network includes a plurality of CSI reporting capabilitydefinition types, after establishing a connection to an access node toperform capability reporting, the UE may generate the capabilityinformation based on a CSI reporting capability definition type selectedby the UE. For example, for a division type of a time-domain unit, theUE may flexibly reflect a calculation processing capability of the UE byusing different time-domain unit division sizes based on a calculationcapability of the UE.

S402. The UE sends the capability information of the UE to an accessnode.

For related descriptions of the capability information, refer toEmbodiment 1 to Embodiment 3. Details are not described herein again.

S403. The UE sends, to the access node, CSI reporting capabilitydefinition type selection indication information selected by the UE.

When the network includes the plurality of CSI reporting capabilitydefinition types, optionally, the UE may indicate, to the access node byusing different signaling formats of the capability information, adefinition type selected by the UE. Optionally, the UE may inform, byusing definition type selection indication information, the access nodeof a definition type selected by the UE. The definition type selectionindication information and the capability information may be senttogether or separately.

For examples of division of the definition type and an indication mannerof the definition type selection indication information, refer torelated descriptions in Embodiment 3. Details are not described hereinagain.

It should be noted that, there is no definite order between S402 andS403. The steps are merely intended to reflect that the UE sends twopieces of information to the access node. If the definition typeselection indication information may be indicated by using differentsignaling formats of the capability information reported by the UE, S403may be omitted. If the definition type selection indication informationand the capability information are sent together, S402 and S403 are onestep.

S404. The access node determines a CSI measurement related configurationof the UE based on the received capability information reported by theUE.

This step is similar to S103, and details are not described hereinagain.

S405. The access node sends information about the CSI measurementrelated configuration to the UE.

The UE performs configuration based on the information about the CSImeasurement related configuration that is sent by the access node, andcompletes CSI measurement and reporting based on the configurationduring subsequent CSI measurement.

According to the terminal device capability reporting method in thisembodiment of this application, the UE indicates, to the access node,the definition type selected by the UE, so that when the system includesa plurality of CSI reporting capability definition types, the accessnode can effectively learn of the CSI reporting capability of the UE,thereby performing effective configuration.

The foregoing embodiments emphasize reporting of the CSI reportingcapability of the UE. After learning of the reporting capability of theUE, the access node may perform CSI measurement related configurationbased on the capability. The following provides descriptions about howthe access node performs CSI measurement related configuration.

FIG. 6 is a schematic diagram of a configuration manner of configuring,by an access node based on a CSI reporting capability of UE, the UE toperiodically or semi-persistently report CSI. There are twoconfiguration manners: a configuration manner 1 and a configurationmanner 2. It is assumed that a CSI reporting capability reported by theUE is that a maximum of four ports (4 ports) can be supported in eachunit, and the unit is divided by one slot. In other words, the CSIreporting capability of the UE is that the UE can support a maximum of 4ports in each slot. Therefore, when configuring CSI measurement andreporting of the UE, the access node needs to consider that the UE cansupport a maximum of 4 ports in each slot. When reporting CSI, the UEneeds to complete a calculation amount for the corresponding CSImeasurement, so as to report the CSI.

As shown in FIG. 6, in the configuration manner 1, the access nodeconfigures the UE to periodically or semi-persistently report CSI. TheCSI is reported every four slot units. The access node configures, inthe first slot unit (slot 0), a channel measurement reference signal set(CMR set) that includes 8 ports and that is used for CSI measurement,and configures, in the second slot unit (slot 1), an interferencemeasurement reference signal set (IMR set) that includes 16 ports andthat is used for CSI measurement. It can be learned that to completechannel measurement and interference measurement, the UE needs tocomplete a calculation amount for 8 ports+16 ports=24 ports. Accordingto the CSI reporting capability of the UE, a maximum of 4 ports can besupported in each slot. In this case, the UE needs at least 6 slots tocomplete measurement calculation for 24 ports. Therefore, if the accessnode configures the calculation amount for CSI measurement with 24 portsin such a manner as the configuration manner 1, the UE cannot beconfigured to report CSI every four slots (for example, in the fifthslot unit (slot 4)). In this case, the UE cannot complete measurement orperform reporting. Therefore, the configuration manner 1 is anunavailable configuration.

As shown in FIG. 6, in the configuration manner 2, the access nodeconfigures the UE to periodically or semi-persistently report CSI.Likewise, the CSI is reported every four slot units. The access nodeconfigures, in the first slot unit, a CMR set that includes 8 ports, andconfigures, in the second slot unit, an IMR set that includes 8 ports.It can be learned that to complete channel measurement and interferencemeasurement, the UE needs to complete a calculation amount for 8 ports+8ports=16 ports. According to the CSI reporting capability of the UE, amaximum of 4 ports can be supported in each slot. In this case, the UEneeds at least four slots to complete measurement calculation for 16ports. In this case, if the access node configures the calculationamount for CSI measurement with 16 ports and a reporting period (everyfour slots) in such a manner as the configuration manner 2, the UE cancomplete corresponding measurement and perform reporting based on theconfiguration. Therefore, the configuration manner 2 is an availableconfiguration.

FIG. 7 is a schematic diagram of a configuration manner of configuring,by an access node based on a CSI reporting capability of UE, the UE toaperiodically report CSI. There are two configuration manners: aconfiguration manner 1 and a configuration manner 2. It is assumed thata CSI reporting capability reported by the UE is that a maximum of 16ports can be supported in each unit, and the unit is divided by oneslot. That is, the CSI reporting capability of the UE is that the UE cansupport a maximum of 16 ports in each slot. Therefore, when configuringCSI measurement and reporting of the UE, the access node needs toconsider that the UE can support a maximum of 16 ports in each slot.When reporting CSI, the UE needs to complete a calculation amount forthe corresponding CSI measurement, so as to report the CSI.

As shown in FIG. 7, in the configuration manner 1, the access nodeconfigures a time offset for aperiodic reporting of the UE. The timeoffset is an interval between a triggering time-domain unit for CSItriggering sent by the access node and a time-domain unit for CSIreporting. As shown in FIG. 7, the time offset Y is configured as 5slots.

For CSI measurement, a plurality of times of measurement and reporting(such as CSI measurement 1 and CSI measurement 2) may be performed inconsideration of various factors (for example, an interference change).For the CSI measurement 1, a quantity of reporting settings configuredfor the UE for reporting is 2, respectively corresponding to a CMR set 1and an IMR set 1, and a CMR set 2 and an IMR set 2. The access nodeconfigures, in the first slot unit (slot 0), the CMR set 1 that includes8 ports and that is used for CSI measurement, configures, in the secondslot unit (slot 1), the CMR set 2 including 16 ports, configures, in thefourth slot unit (slot 3), the IMR set 1 that includes 8 ports and thatis used for CSI measurement, and configures, in the fifth slot unit(slot 4), the IMR set 2 including 16 ports. It can be learned that atotal calculation amount for the CSI measurement 1 to be calculated bythe UE is 8+16+8+16=48 ports.

For the CSI measurement 2, a quantity of reporting settings configuredfor the UE for reporting is 2, respectively corresponding to a CMR set 1and an IMR set 3, and a CMR set 2 and an IMR set 4. The IMR set 3including 8 ports is configured in the seventh slot unit (slot 6), andthe IMR set 4 including 16 ports is configured in the eighth slot unit(slot 7). It can be learned that a total calculation amount for the CSImeasurement 2 to be calculated by the UE is 8+16+8+16=48 ports.

It can be learned that for the CSI measurement 1, to completecalculation for 48 ports, the UE needs at least 48/16=3 slots. If theaccess node configures that the CSI measurement 1 is triggered in slot3, the UE can complete the CSI measurement 1 and perform reporting inslot 8 after the configured time offset Y, namely, 5 slots. Therefore,the configuration of the time offset and the calculation amount for theCSI measurement 1 is available. Likewise, the configuration of the timeoffset and the calculation amount for the CSI measurement 2 is alsoavailable.

However, if for the CSI measurement 2, the access node configures thatthe CSI measurement 2 is triggered in slot 5, the UE is calculating theCSI measurement 1 at this moment, and has not finished calculation. Inthis case, this is beyond a capability of the UE, and the access nodecannot configure that the CSI measurement 2 is triggered at this moment.Therefore, the configuration is unavailable.

As shown in FIG. 7, in the configuration manner 2, other conditionsremain unchanged. If the access node configures that the CSI measurement2 is triggered in slot 6, the UE is idle currently, and the access nodemay trigger new CSI reporting. The access node may configure triggeringat this moment. The configuration is available.

FIG. 8 is another schematic diagram of a configuration manner ofconfiguring, by an access node based on a CSI reporting capability ofUE, the UE to aperiodically report CSI. There are two configurationmanners: a configuration manner 1 and a configuration manner 2. It isassumed that a CSI reporting capability reported by the UE is that amaximum of 16 ports can be supported in each unit, and the unit isdivided by one slot. In other words, the CSI reporting capability of theUE is that the UE can support a maximum of 16 ports in each slot.Therefore, when configuring CSI measurement and reporting of the UE, theaccess node needs to consider that the UE can support a maximum of 16ports in each slot. When reporting CSI, the UE needs to complete acalculation amount for the corresponding CSI measurement, so as toreport the CSI.

As shown in FIG. 8, in the configuration manner 1, the access nodeconfigures a time offset configured by the access node for aperiodicreporting of the UE is still 5 slots. For the CSI measurement 1, aquantity of reporting settings configured for the UE for reporting is 2,respectively corresponding to a CMR set 1 and an IMR set 1, and a CMRset 2 and an IMR set 2. The access node configures, in the first slotunit (slot 0), the CMR set 1 that includes 8 ports and that is used forCSI measurement, configures, in the second slot unit (slot 1), the CMRset 2 including 16 ports, configures, in the sixth slot unit (slot 5),the IMR set 1 that includes 8 ports and that is used for CSImeasurement, and configures, in the seventh slot unit (slot 6), the IMRset 2 including 16 ports. It can be learned that a total calculationamount for the CSI measurement 1 to be calculated by the UE is8+16+8+16=48 ports.

For the CSI measurement 2, a quantity of reporting settings configuredfor the UE for reporting is 2, respectively corresponding to a CMR set 1and an IMR set 3, and a CMR set 2 and an IMR set 4. The IMR set 3including 8 ports is sent in the seventh slot unit (slot 6), and the IMRset 4 including 16 ports is sent in the eighth slot unit (slot 7). Itcan be learned that a total calculation amount for the CSI measurement 2to be calculated by the UE is 8+16+8+16=48 ports.

It can be learned that for the CSI measurement 1, to completecalculation for 48 ports, the UE needs at least 48/16=3 slots. However,it should be noted that in addition to the total calculation time, whenperforming configuration, the access node further needs to consider arelationship between a time of delivering a CMR set and an IMR set and areporting time of the UE. For example, according to the configurationmanner 1, if the access node triggers reporting of the CSI measurement 1at the end of slot 1, after a preconfigured time offset, the UE needs toperform reporting at the end of slot 6. The IMR set 1 (8 ports) and theIMR set 2 (16 ports) are respectively delivered in slot 5 and slot 6.The UE is not idle in slot 6 yet, and needs to process calculation of aninterference measurement setting. Therefore, the access node cannotconfigure that reporting of the CSI measurement 2 is triggered in slot6, and can trigger the CSI measurement 2 at least at the end of slot 6after the UE completes calculation of the CSI measurement 1. Inaddition, it should further be noted that, if the IMR set 1 and the IMRset 2 are respectively delivered in slot 5 and slot 6, the UE needs toperform reporting at the end of slot 6. If a sum of quantities of portsof the IMR set 1 and the IMR set 2 exceeds a quantity of ports supportedby the UE in the two units, that is, 32 ports, the UE also cannotcomplete a calculation amount for the configuration in slot 6, andconsequently, cannot perform reporting.

As shown in FIG. 8, in the configuration manner 2, other conditionsremain unchanged. If the quantity of ports of the IMR set 2 changes to 8ports, and the CSI measurement 2 is triggered in slot 5, the UE has acalculation capability of remaining 8 ports in both slot 5 and slot 6.Although in this case (slot 5 and slot 6), the configured IMR set 3 andIMR set 4 are not received, the base station can trigger new CSIreporting, and the UE may first calculate the CMR set 1 (8 ports) knownin the CSI measurement 2. Therefore, the access node may configure thatthe CSI measurement 2 is triggered at this moment (in slot 5), and theconfiguration is available. It may be understood that in theconfiguration manner, the UE supports parallel processing. When thecalculation capability is surplus, the UE may perform parallelcalculation. That the UE supports parallel processing is considered ashaving a stronger UE capability for CSI reporting. One or more reportingsettings may be configured if an average quantity of pilot ports in eachtime-domain unit is not greater than the UE capability before the CSIreporting.

It should be noted that the foregoing descriptions about theconfiguration manners are specifically for a case in which the CSIreporting capability of the UE is a maximum quantity, and supported ineach time-domain unit, of ports of pilots used for CSI measurement. Theconfiguration manners are merely examples for description, providedescriptions about how to configure the CSI reporting capability of theUE, and are not intended to limit this application. For differentdefinition cases of the CSI reporting capability of the UE, theconfiguration logic in the foregoing examples is followed. The CSImeasurement and reporting of the UE that are configured by the accessnode should not exceed the CSI reporting capability of the UE, so thatthe UE can complete the CSI measurement and reporting.

The foregoing describes the solutions provided in the embodiments ofthis application mainly by using a procedure in which various entitiesin the system interact with each other to perform parallel transmissioncontrol. It may be understood that to implement the foregoing functions,the foregoing various entities include hardware structures and/orsoftware modules corresponding to the various functions. A personskilled in the art should be easily aware that, in combination with theunits and algorithm steps of the examples described in the embodimentsdisclosed in this specification, this application can be implemented byhardware or a combination of hardware and computer software. Whether afunction is performed by hardware or by computer software drivinghardware depends on particular applications and design constraintconditions of the technical solutions. A person skilled in the art mayuse different methods to implement the described functions for eachparticular application, but it should not be considered that theimplementation goes beyond the scope of this application.

In the embodiments of this application, function module division may beperformed on the UE and the access node according to the examples of themethods. For example, various function modules may be divided accordingto the corresponding functions, or two or more functions may beintegrated into one processing module. The integrated module may beimplemented in a form of hardware, or may be implemented in a form of asoftware function module. It should be noted that module division in theembodiments of this application is an example and is merely logicalfunction division. During actual implementation, there may be anotherdivision manner. The following descriptions are made by using an examplein which function modules are divided corresponding to functions.

An embodiment of this application further provides a terminal device.The terminal device may be configured to perform the steps performed bythe UE in any one of FIG. 2 to FIG. 5. FIG. 9 is a simplified schematicstructural diagram of the terminal device. For ease of understanding andconvenience of figure illustration, an example in which the terminaldevice is a mobile phone is used in FIG. 9. As shown in FIG. 9, theterminal device 90 includes a processor, a memory, a radio frequencycircuit, an antenna, and an input/output apparatus. The processor ismainly configured to: process a communication protocol and communicationdata, control the terminal device 90, execute a software program,process data of the software program, and the like. The memory is mainlyconfigured to store the software program and data. The radio frequencycircuit is mainly configured to: perform conversion between a basebandsignal and a radio frequency signal, and process the radio frequencysignal. The antenna is mainly configured to receive and send a radiofrequency signal in a form of an electromagnetic wave. The input/outputapparatus, such as a touchscreen, a display, or a keyboard, is mainlyconfigured to: receive data entered by a user and output data to theuser. It should be noted that terminal devices 90 of some types may nothave the input/output apparatus. The memory and the processor may beintegrated together or may be disposed independently. In addition, theradio frequency circuit and the processor may be integrated together ormay be disposed independently.

When needing to send data, after performing baseband processing on thedata to be sent, the processor outputs a baseband signal to the radiofrequency circuit. The radio frequency circuit performs radio frequencyprocessing on the baseband signal and sends a radio frequency signal tooutside in a form of an electromagnetic wave by using the antenna. Whendata is sent to the terminal device 90, the radio frequency circuitreceives a radio frequency signal by using the antenna, converts theradio frequency signal into a baseband signal, and outputs the basebandsignal to the processor. The processor converts the baseband signal intodata, and processes the data. For ease of description, FIG. 9 shows onlyone memory and processor. In an actual terminal device product, theremay be one or more processors and one or more memories. The memory mayalso be referred to as a storage medium, a storage device, or the like.The memory may be disposed independent of the processor, or may beintegrated with the processor. This is not limited in this embodiment ofthis application.

In this embodiment of this application, the antenna and the radiofrequency circuit having transmission and receiving functions may beconsidered as a transceiver unit of the terminal device 90, and theprocessor having a processing function may be considered as a processingunit of the terminal device 90. As shown in FIG. 9, the terminal device90 includes a transceiver unit 901 and a processing unit 902. Thetransceiver unit may also be referred to as a transceiver (including atransmitter and/or a receiver), a transceiver machine, a transceiverapparatus, a transceiver circuit, or the like. The processing unit mayalso be referred to as a processor, a processing board, a processingmodule, a processing apparatus, or the like. Optionally, a component forimplementing a receiving function in the transceiver unit 901 may beconsidered as a receiving unit, and a component for implementing asending function in the transceiver unit 901 may be considered as asending unit. That is, the transceiver unit 901 includes a receivingunit and a sending unit. The transceiver unit may also be referred to asa transceiver machine, a transceiver, a transceiver circuit, or the likesometimes. The receiving unit may also be referred to as a receivermachine, a receiver, a receiver circuit, or the like sometimes. Thesending unit may also be referred to as a transmitter machine, atransmitter, a transmitter circuit, or the like sometimes. In someembodiments, the transceiver unit 901 and the processing unit 902 may beintegrated together or may be disposed independently. In addition, allfunctions of the processing unit 902 may be integrated into one chip forimplementation. Alternatively, some functions may be integrated into onechip for implementation and some other functions are integrated into oneor more other chips for implementation. This is not limited in thisapplication. The term “unit” used in this specification may refer to anapplication-specific integrated circuit (ASIC), an electronic circuit, aprocessor (shared, dedicated, or group) and memory, or a combinationallogic circuit that executes one or more software or firmware programs,and/or other suitable components that provide the function.

For example, in an implementation, the transceiver unit 901 isconfigured to perform the steps performed by the UE in S102 and/or S104in FIG. 2, and/or other steps in this application. The processing unit902 is configured to perform S101 in FIG. 2, and/or other steps in thisapplication.

For example, in another implementation, the transceiver unit 901 isconfigured to perform the steps performed by the UE in S202 and/or S204in FIG. 3, and/or other steps in this application. The processing unit902 is configured to perform S201 in FIG. 3, and/or other steps in thisapplication.

For example, in another implementation, the transceiver unit 901 isconfigured to perform the steps performed by the UE in S301, S303,and/or S305 in FIG. 4, and/or other steps in this application. Theprocessing unit 902 is configured to perform S302 in FIG. 4, and/orother steps in this application.

For example, in another implementation, the transceiver unit 901 isconfigured to perform the steps performed by the UE in S402, S403,and/or S405 in FIG. 5, and/or other steps in this application. Theprocessing unit 902 is configured to perform S401 in FIG. 5, and/orother steps in this application.

An embodiment of this application further provides a network device. Thenetwork device may serve as an access node or a transmission andreception point, and is configured to perform the steps performed by theaccess node in any one of FIG. 2 to FIG. 5. FIG. 10 is a simplifiedschematic structural diagram of the network device. The network device10 includes a part 1001 and a part 1002. The part 1001 is mainlyconfigured to receive and send a radio frequency signal and performconversion between the radio frequency signal and a baseband signal. Thepart 1002 is mainly configured to perform baseband processing, controlthe network device 10, and the like. The part 1001 may be usuallyreferred to as a transceiver unit, a transceiver machine, a transceivercircuit, a transceiver, or the like. The part 1002 is usually a controlcenter of the network device 10, and may usually be referred to as aprocessing unit, a control unit, a processor, a controller, or the like,configured to control the network device 10 to perform steps performedby a measurement functional entity on an access side or by the accessnode/the transmission and reception point used as a measurementfunctional entity on an access side in the foregoing relatedembodiments. For details, refer to the foregoing descriptions of therelated part.

A transceiver unit of the part 1001 may also be referred to as atransceiver machine, a transceiver, or the like. The transceiver unitincludes an antenna and a radio frequency unit. The radio frequency unitis mainly configured to perform radio frequency processing. Optionally,a component for implementing a receiving function in the part 1001 maybe considered as a receiving unit, and a component for implementing asending function may be considered as a sending unit. That is, the part1001 includes a receiving unit and a sending unit. The receiving unitmay also be referred to as a receiver machine, a receiver, a receivercircuit, or the like. The sending unit may also be referred to as atransmitter machine, a transmitter, a transmitter circuit, or the like.

The part 1002 may include one or more boards. Each board may include oneor more processors and one or more memories. The processor is configuredto read and execute a program in the memory, to implement a basebandprocessing function and control the network device 10. If there are aplurality of boards, the boards may be interconnected to enhance aprocessing capability. In an optional implementation, alternatively, theplurality of boards may share one or more processors, or the pluralityof boards share one or more memories, or the plurality of boards shareone or more processors at the same time. The memory and the processormay be integrated together or may be disposed independently. In someembodiments, the part 1001 and the part 1002 may be integrated togetheror may be disposed independently. In addition, all functions of the part1002 may be integrated into one chip for implementation. Alternatively,some functions may be integrated into one chip for implementation andsome other functions are integrated into one or more other chips forimplementation. This is not limited in this application.

For example, in an implementation, the transceiver unit may beconfigured to perform the steps performed by the access node in S102and/or S104 in FIG. 2, and/or other steps in this application. Theprocessing unit is configured to perform S103 in FIG. 2, and/or othersteps in this application.

For example, in another implementation, the transceiver unit isconfigured to perform the steps performed by the access node in S202and/or S204 in FIG. 3, and/or other steps in this application. Theprocessing unit is configured to perform S203 in FIG. 3, and/or othersteps in this application.

For example, in another implementation, the transceiver unit isconfigured to perform the steps performed by the access node in S301,S303, and/or S305 in FIG. 4, and/or other steps in this application. Theprocessing unit is configured to perform S304 in FIG. 4, and/or othersteps in this application.

For example, in another implementation, the transceiver unit isconfigured to perform the steps performed by the access node in S402,S403, and/or S406 in FIG. 5, and/or other steps in this application. Theprocessing unit is configured to perform S404 in FIG. 5, and/or othersteps in this application.

The apparatus on a terminal side provided above may be a terminaldevice, or may be a chip or a function module in a terminal device, andmay implement the foregoing method by software or hardware, or byhardware executing corresponding software.

A specific implementation of the apparatus on a network side providedabove may be an access node device. For example, the apparatus may be anaccess node device, or a chip or a function module in an access nodedevice, and may implement the foregoing method by software or hardware,or by hardware executing corresponding software.

For descriptions of related content and beneficial effects of anyterminal device, network device, and corresponding apparatus providedabove, refer to the corresponding method embodiments provided above.Details are not described herein again.

This application further provides a terminal device capabilitytransmission system. The system includes the UE (which may also be aUE-side apparatus implementing functions of the foregoing UE) and theaccess node (which may also be an access-side apparatus or atransmission and reception point implementing the foregoing access nodefunction) in the foregoing implementations.

This application further provides a computer program product. When thecomputer program product runs on a computer, the computer performs anymethod provided above.

This application further provides a chip, storing an instruction. Whenthe instruction runs on each of the foregoing devices, the deviceperforms the method provided above.

This application further provides a computer storage medium, storing acomputer program (instruction). When the program (instruction) runs on acomputer, the computer performs the method provided above.

All or some of the foregoing embodiments may be implemented by usingsoftware, hardware, firmware, or any combination thereof. When softwareis used to implement the embodiments, the embodiments may be implementedcompletely or partially in a form of a computer program product. Thecomputer program product includes one or more computer instructions.When the computer program instructions are loaded and executed on thecomputer, the procedure or functions according to the embodiments ofthis application are all or partially generated. The computer may be ageneral-purpose computer, a dedicated computer, a computer network, oranother programmable apparatus. The computer instructions may be storedin a computer-readable storage medium or may be transmitted from acomputer-readable storage medium to another computer-readable storagemedium. For example, the computer instructions may be transmitted from awebsite, computer, server, or data center to another website, computer,server, or data center in a wired (for example, a coaxial cable, anoptical fiber, or a digital subscriber line (DSL)) or wireless (forexample, infrared, radio, and microwave, or the like) manner. Thecomputer-readable storage medium may be any available medium accessibleby a computer, or a data storage device, such as a server or a datacenter, integrating one or more available media. The available mediummay be a magnetic medium (for example, a soft disk, a hard disk, or amagnetic tape), an optical medium (for example, a DVD), a semiconductormedium (for example, a solid state disk (SSD)), or the like.

A proposal of the foregoing solutions in New Radio (New Radio, NR forshort) is as follows:

Actually, for each reporting setting, the actual UE capability for CSIreporting depends on how much workload UE can afford for calculating CSIinfo based on the CSI-RS resources configured in resource settingslinked with the reporting setting. The total number of CSI-RS ports ineach unit UE can afford can reflect the UE capability for CSI reporting.UE capability for CSI reporting can be defined as the maximum number ofCSI-RS ports for each unit UE afford for update CSI. For UE supportsprocessing in parallel would have a large UE capability for CSIreporting. One or more reporting settings can be configured if theaverage number of CSI-RS ports for each unit before CSI reporting is nolarger than the UE capability.

Then we can the following proposal:

Proposal XX: UE capability for CSI reporting can be defined as themaximum number of CSI-RS ports for each unit UE afford for update CSI.

It can be learned that in the proposal, a total quantity of CSI-RS portsin each unit the UE can afford may reflect the UE capability for CSIreporting. The UE capability for CSI reporting may be defined as themaximum quantity of CSI-RS ports in each unit UE affords for CSI update.The UE that supports processing in parallel would have a larger UEcapability for CSI reporting. One or more reporting settings may beconfigured if an average quantity of CSI-RS ports in each unit is notgreater than the UE capability before the CSI reporting.

Finally, preferably, a preferred solution in the proposal is that the UEcapability for CSI reporting may be defined as the maximum quantity ofCSI-RS ports in each unit supported by the UE for CSI update.

Although this application is described with reference to theembodiments, in a process of implementing this application that claimsprotection, a person skilled in the art may understand and implementanother variation of the disclosed embodiments by viewing theaccompanying drawings, disclosed content, and the accompanying claims.In the claims, “comprising” does not exclude another component oranother step, and “a” or “one” does not exclude a case of multiple. Asingle processor/controller or another unit may implement severalfunctions enumerated in the claims. Some measures are recorded independent claims that are different from each other, but this does notmean that these measures cannot be combined to produce a better effect.

Although this application is described with reference to specificfeatures and the embodiments thereof, obviously, various modificationsand combinations may be made to them without departing from the essenceand scope of this application. Correspondingly, the specification andaccompanying drawings are merely example description of this applicationdefined by the accompanying claims, and is considered as any of or allmodifications, variations, combinations or equivalents that cover thescope of this application. Obviously, a person skilled in the art canmake various modifications and variations to this application withoutdeparting from the essence and scope of this application. Thisapplication is intended to cover these modifications and variations ofthis application provided that they fall within the scope of protectiondefined by the following claims and their equivalent technologies.

What is claimed is:
 1. A terminal device, comprising: a processor; and atransceiver coupled to the processor and configured to: transmitcapability information of the terminal device to a network device,wherein the capability information includes channel state information(CSI) reporting capability information indicating a maximum quantity,supported in a slot, of ports of reference signals used for CSImeasurement, and wherein the CSI reporting capability informationincludes at least one of: information of a first CSI reportingcapability corresponding to codebook type I, or information of a secondCSI reporting capability corresponding to codebook type II; receive aCSI measurement related configuration related to the capabilityinformation of the terminal device from the network device; and receiveat least one reference signal from the network device; wherein theprocessor is configured to perform a channel measurement based on thereceived reference signal, and the transceiver is configured to transmita result of the channel measurement to the network device.
 2. Theterminal device according to claim 1, wherein the CSI reportingcapability information includes the information of the first CSIreporting capability corresponding to codebook type I, and theinformation of the second CSI reporting capability corresponding tocodebook type II.
 3. The terminal device according to claim 1, whereinthe capability information is indicated by using a bit in a bitmap or byusing a value of an indication field.
 4. The terminal device accordingto claim 1, wherein: the maximum quantity of ports of the referencesignals used for CSI measurement comprises at least one of thefollowing: a quantity of ports of reference signals used for channelmeasurement, a sum of the quantity of ports of the reference signalsused for channel measurement and a quantity of ports of referencesignals used for interference measurement, or a weighted sum of thequantity of ports of the reference signals used for channel measurementand the quantity of ports of the reference signals used for interferencemeasurement.
 5. A processing apparatus, comprising at least oneprocessor, wherein the at least one processor is configured to read aninstruction in a memory, and implement: causing a transceiver totransmit capability information of a terminal device to a networkdevice, wherein the capability information includes channel stateinformation (CSI) reporting capability information indicating a maximumquantity, supported in a slot, of ports of reference signals used forCSI measurement, and wherein the CSI reporting capability informationincludes at least one of: information of a first CSI reportingcapability corresponding to codebook type I, or information of a secondCSI reporting capability corresponding to codebook type; causing thetransceiver to receive a CSI measurement related configuration relatedto the capability information of the terminal device from the networkdevice; causing the transceiver to receive at least one reference signalfrom the network device; performing a channel measurement based on thereceived reference signal; and causing the transceiver to transmit aresult of the channel measurement to the network device.
 6. Theprocessing apparatus according to claim 5, wherein the CSI reportingcapability information includes the information of the first CSIreporting capability corresponding to codebook type I, and theinformation of the second CSI reporting capability corresponding tocodebook type II.
 7. The processing apparatus according to claim 5,wherein the capability information is indicated by using a bit in abitmap or by using a value of an indication field.
 8. The processingapparatus according to claim 5, wherein: the maximum quantity of portsof the reference signals used for CSI measurement comprises at least oneof the following: a quantity of ports of reference signals used forchannel measurement, a sum of the quantity of ports of the referencesignals used for channel measurement and a quantity of ports ofreference signals used for interference measurement, or a weighted sumof the quantity of ports of the reference signals used for channelmeasurement and the quantity of ports of the reference signals used forinterference measurement.
 9. A method for reporting capabilityinformation of a terminal device in a wireless communication system,comprising: transmitting capability information of a terminal device toa network device, wherein the capability information includes channelstate information (CSI) reporting capability information indicating amaximum quantity, supported in a slot, of ports of reference signalsused for CSI measurement, and wherein the CSI reporting capabilityinformation includes at least one of: information of a first CSIreporting capability corresponding to codebook type I, or information ofa second CSI reporting capability corresponding to codebook type;receiving a CSI measurement related configuration related to thecapability information of the terminal device from the network device;receiving at least one reference signal from the network device;performing a channel measurement based on the received reference signal;and transmitting a result of the channel measurement to the networkdevice.
 10. The method according to claim 9, wherein the CSI reportingcapability information includes the information of the first CSIreporting capability corresponding to codebook type I, and theinformation of the second CSI reporting capability corresponding tocodebook type II.
 11. The method according to claim 9, wherein thecapability information is indicated by using a bit in a bitmap or byusing a value of an indication field.
 12. The method according to claim9, wherein the maximum quantity of ports of the reference signals usedfor CSI measurement comprises at least one of the following: a quantityof ports of reference signals used for channel measurement, a sum of thequantity of ports of the reference signals used for channel measurementand a quantity of ports of reference signals used for interferencemeasurement, or a weighted sum of the quantity of ports of the referencesignals used for channel measurement and the quantity of ports of thereference signals used for interference measurement.
 13. Anon-transitory computer-readable storage medium, storing a computerprogram, wherein when executing the program, a computer implements:transmitting capability information of a terminal device to a networkdevice, wherein the capability information includes channel stateinformation (CSI) reporting capability information indicating a maximumquantity, supported in a slot, of ports of reference signals used forCSI measurement, and wherein the CSI reporting capability informationincludes at least one of: information of a first CSI reportingcapability corresponding to codebook type I, or information of a secondCSI reporting capability corresponding to codebook type; receiving a CSImeasurement related configuration related to the capability informationof the terminal device from the network device; receiving at least onereference signal from the network device; performing a channelmeasurement based on the received reference signal; and transmitting aresult of the channel measurement to the network device.
 14. Thenon-transitory computer-readable storage medium according to claim 13,wherein the CSI reporting capability information includes theinformation of the first CSI reporting capability corresponding tocodebook type I, and the information of the second CSI reportingcapability corresponding to codebook type II.
 15. The non-transitorycomputer-readable storage medium according to claim 13, wherein thecapability information is indicated by using a bit in a bitmap or byusing a value of an indication field.
 16. The non-transitorycomputer-readable storage medium according to claim 13, wherein themaximum quantity of ports of the reference signals used for CSImeasurement comprises at least one of the following: a quantity of portsof reference signals used for channel measurement, a sum of the quantityof ports of the reference signals used for channel measurement and aquantity of ports of reference signals used for interferencemeasurement, or a weighted sum of the quantity of ports of the referencesignals used for channel measurement and the quantity of ports of thereference signals used for interference measurement.